static int __init ipera_init(void)
{
int ret;
__D("** " __FILE__ " kernel module built: " __DATE__ " " __TIME__ "\n");
ret = register_chrdev(major, K_DEV, &ipera_fops);
if (ret < 0) {
__E("Failed to allocate major number.\n");
return -ENODEV;
}
__D("Allocated major number: %d\n", major);
#ifdef USE_UDEV
ipera_class = class_create(THIS_MODULE, K_DEV);
if (IS_ERR(ipera_class)) {
__E("Error creating ipera device class.\n");
return -EIO;
}
//class_device_create(ipera_class, NULL, MKDEV(major, 0), NULL, K_DEV);
#endif // USE_UDEV
__D("Successfully initialized module\n");
return 0;
}
/**
* @brief Video read frame
* @param "void *pDest" : destination address
* @param "int *pSize" : size
* @param "int *pFrm_type" : frame type
* @param "int bufflimit" : buffer limit
* @param "VIDEO_FRAME *pFrame"
* @param "VIDEO_BLK_INFO *pVidInfo"
* @return 0 : success ; -1 : fail
*/
int MemMng_Video_ReadFrame( void *pDest, int *pSize, int *pFrm_type , int bufflimit,
VIDEO_FRAME *pFrame, VIDEO_BLK_INFO *pVidInfo )
{
if( pDest == NULL || pVidInfo == NULL || pFrame == NULL )
{
__E("MemMng_Video_ReadFrame: invalidate pointer\n");
return -1;
}
if( pFrame->fram_type == DUMMY_FRAME || pFrame->fram_type == EMPTY_FRAME )
{
__E("MemMng_Video_ReadFrame: invalidate frame_type\n");
return -1;
}
if( pFrame->realsize > bufflimit )
{
__E("MemMng_Video_ReadFrame: Over bufflimit\n");
return -1;
}
void *pSrc = (void *)(pVidInfo->start +
pFrame->blkindex*pVidInfo->blk_sz);
*pSize = pFrame->realsize;
*pFrm_type = pFrame->fram_type;
MemMng_memcpy( pDest, pSrc, pFrame->realsize );
return 0;
}
static int validate_init()
{
switch (cmem_fd) {
case -3:
__E("CMEM_exit() already called, check stderr output for earlier "
"CMEM failure messages (possibly version mismatch).\n");
return 0;
case -2:
__E("CMEM_init() not called, you must initialize CMEM before "
"making API calls.\n");
return 0;
case -1:
__E("CMEM file descriptor -1 (failed 'open()'), ensure CMEMK "
"kernel module cmemk.ko has been installed with 'insmod'");
return 0;
default:
return 1;
}
}
EnemyInst::EnemyInst(int enemytype, int x, int y) :
CombatGameInst(__E(enemytype).basestats,
__E(enemytype).enemy_sprite, x, y,
__E(enemytype).radius, true, DEPTH) {
this->seen = false;
this->xpgain = __E(enemytype).xpaward;
this->enemytype = enemytype;
this->enemy_regen_cooloff = 0;
}
/* RGB Buffer Allocation */
static int camif_pp_preview(camif_cfg_t *cfg)
{
int i;
u32 cbcr_size = 0; /* Cb,Cr size */
u32 area = cfg->target_x * cfg->target_y;
__D("\n");
if(cfg->input_channel) {
camif_pp_preview_msdma(cfg);
return 0;
}
if (cfg->dst_fmt & CAMIF_YCBCR420) {
cbcr_size = area /4;
/* To Do */
} else if(cfg->dst_fmt & CAMIF_YCBCR422){
cbcr_size = area /2;
/* To Do */
} else if(cfg->dst_fmt & CAMIF_RGB24) {
area = area * 4 ;
} else if (cfg->dst_fmt & CAMIF_RGB16) {
area = area * 2;
} else {
__E("Invalid format No - %d \n", cfg->dst_fmt);
}
switch ( cfg->pp_num ) {
case 1:
for ( i = 0; i < 4 ; i++ ) {
cfg->img_buf[i].virt_rgb = cfg->pp_virt_buf ;
cfg->img_buf[i].phys_rgb = cfg->pp_phys_buf ;
base->CIPRYSA[i] = cfg->img_buf[i].phys_rgb;
}
break;
case 2:
for ( i = 0; i < 4 ; i++) {
cfg->img_buf[i].virt_rgb = cfg->pp_virt_buf + TRY * area;
cfg->img_buf[i].phys_rgb = cfg->pp_phys_buf + TRY * area;
base->CIPRYSA[i] = cfg->img_buf[i].phys_rgb;
}
break;
case 4:
for ( i = 0; i < 4 ; i++) {
cfg->img_buf[i].virt_rgb = cfg->pp_virt_buf + i * area;
cfg->img_buf[i].phys_rgb = cfg->pp_phys_buf + i * area;
base->CIPRYSA[i] = cfg->img_buf[i].phys_rgb;
}
break;
default:
__E("Invalid PingPong Number %d \n", cfg->pp_num);
}
return 0;
}
int __init gbshm_init(void)
{
int err = 0;
/* cut-and-paste above as part of adding support for more than 2 blocks */
gbshm_major = register_chrdev(0, "vidctl", &gbshm_fxns);
if (gbshm_major < 0) {
__E("Failed to allocate major number.\n");
return -ENODEV;
}
__D("Allocated major number: %d\n", gbshm_major);
#if (USE_UDEV==1)
#ifdef USE_CLASS_SIMPLE
gbshm_class = class_simple_create(THIS_MODULE, "gbshm");
#else
gbshm_class = class_create(THIS_MODULE, "gbshm");
#endif
if (IS_ERR(gbshm_class)) {
__E("Error creating cmem device class.\n");
err = -EIO;
return err;
}
#ifdef USE_CLASS_SIMPLE
class_simple_device_add(gbshm_class, MKDEV(gbshm_major, 0), NULL, "gbshm");
#else
#ifdef USE_CLASS_DEVICE
class_device_create(gbshm_class, NULL, MKDEV(gbshm_major, 0), NULL, "gbshm");
#else
#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,27)
device_create(gbshm_class, NULL, MKDEV(gbshm_major, 0), NULL, "gbshm");
#else
device_create(gbshm_class, NULL, MKDEV(gbshm_major, 0), "gbshm");
#endif // LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,27)
#endif // USE_CLASS_DEVICE
#endif // USE_CLASS_SIMPLE
#endif // USE_UDEV
/* Create the /proc entry */
printk(KERN_INFO "vidctl initialized\n");
//set_reg();
//printk_reg();
//tvp5150_set_input_mux(0);
return 0;
}
/* RGB Buffer Allocation For CODEC path */
static int camif_pp_codec_rgb(camif_cfg_t *cfg)
{
int i;
u32 val;
u32 area = cfg->target_x * cfg->target_y;
__D("\n");
if(cfg->dst_fmt & CAMIF_RGB24) {
area = area * 4 ;
} else if (cfg->dst_fmt & CAMIF_RGB16){
area = area * 2;
} else {
__E("Failed! %d\n", cfg->dst_fmt);
}
if(cfg->input_channel == MSDMA_FROM_CODEC){ // Use MSDMA
val = readl(S3C_VIDW00ADD0B0);
for ( i = 0; i < 4 ; i++ ) {
base->CICOYSA[i] = val;
}
} else{ // Do NOT use MSDMA
switch ( cfg->pp_num ) {
case 1:
for ( i = 0; i < 4 ; i++ ) {
cfg->img_buf[i].virt_rgb = cfg->pp_virt_buf ;
cfg->img_buf[i].phys_rgb = cfg->pp_phys_buf ;
base->CICOYSA[i] = cfg->img_buf[i].phys_rgb;
}
break;
case 2:
for ( i = 0; i < 4 ; i++) {
cfg->img_buf[i].virt_rgb = cfg->pp_virt_buf + TRY * area;
cfg->img_buf[i].phys_rgb = cfg->pp_phys_buf + TRY * area;
base->CICOYSA[i] = cfg->img_buf[i].phys_rgb;
}
break;
case 4:
for ( i = 0; i < 4 ; i++) {
cfg->img_buf[i].virt_rgb = cfg->pp_virt_buf + i * area;
cfg->img_buf[i].phys_rgb = cfg->pp_phys_buf + i * area;
base->CICOYSA[i] = cfg->img_buf[i].phys_rgb;
}
break;
default:
__E("Invalid PingPong Number %d \n",cfg->pp_num);
panic("s3c_camif.c : Halt !\n");
}
}
return 0;
}
int DM365MM_clearPending (void)
{
if (dm365mm_fd == -1)
{
__E ("clearPending: invalid fd\n");
return -1;
}
if (ioctl (dm365mm_fd, DM365MMAP_IOCCLEAR_PENDING, NULL) == -1)
{
__E ("clearPending: Clear Pending failed.\n");
return -1;
}
return 0;
}
/**
* @brief Video memory allocate
* @param "MEM_MNG_INFO *pInfo"
* @return 0 : success ; -1 : fail
*/
int Video_Mem_Malloc( MEM_MNG_INFO *pInfo )
{
int cnt = 0;
int loops = 0;
int cnt2 = 0;
loops = sizeof( Video_info_default )/ sizeof( Video_info_default[0] );
pInfo->video_info_nums = loops;
pInfo->video_info = calloc( pInfo->video_info_nums, sizeof(VIDEO_BLK_INFO) );
memcpy( pInfo->video_info, Video_info_default, sizeof( Video_info_default ) );
for( cnt = 0; cnt < loops ; cnt++ )
{
pInfo->video_info[cnt].start = pInfo->start_addr + pInfo->offset;
pInfo->video_info[cnt].start_phy = pInfo->start_phyAddr + pInfo->offset;;
pInfo->video_info[cnt].frame_num = pInfo->video_info[cnt].blk_num;
pInfo->video_info[cnt].frame = calloc( pInfo->video_info[cnt].blk_num ,
sizeof(VIDEO_FRAME) );
for( cnt2 = 0; cnt2 < pInfo->video_info[cnt].blk_num ; cnt2++ )
{
Video_Frame_reset( &(pInfo->video_info[cnt].frame[cnt2]) );
}
pInfo->freesize -= pInfo->video_info[cnt].size;
pInfo->offset += pInfo->video_info[cnt].size;
if( pInfo->video_info[cnt].extrasize > 0 )
{
pInfo->video_info[cnt].extradata = (void *)(pInfo->start_addr + pInfo->offset);
pInfo->freesize -= pInfo->video_info[cnt].extrasize;
pInfo->offset += pInfo->video_info[cnt].extrasize;
}
if( pInfo->freesize < 0 || pInfo->video_info[cnt].frame == NULL)
{
__E("pInfo->freesize = %d\n",pInfo->freesize);
__E("Video_Mem_Malloc FAIL\n");
return -1;
}
}
return 0;
}
int DM365MM_waitForSequencer (void)
{
if (dm365mm_fd == -1)
{
__E ("waitForSequencer: invalid fd\n");
return -1;
}
if (ioctl (dm365mm_fd, DM365MMAP_IOCWAIT, NULL) == -1)
{
__E
("waitForSequencer: Wait failed, process interrupted in between.\n");
return -1;
}
return 0;
}
/**
* @brief Memory manager initialization
* @param "MEM_MNG_INFO *pInfo"
* @return 0 : success ; -1 : fail
*/
int MemMng_Init( MEM_MNG_INFO *pInfo )
{
int mem_layout = pInfo->mem_layout;
memset( pInfo, 0 , sizeof(MEM_MNG_INFO) );
pInfo->totalsize = MemMng_Mem_layout(mem_layout);
pInfo->start_addr = (unsigned long)STREAM_CMEM_ALLOC(pInfo->totalsize, 32);
if( pInfo->start_addr == 0 )
goto MEM_INIT_FAIL;
pInfo->start_phyAddr = CMEM_getPhys((void *)pInfo->start_addr);
if(pInfo->start_phyAddr == 0)
fprintf(stderr, "Failed to get physical address of %#x\n",
(unsigned int) pInfo->start_phyAddr);
pInfo->freesize = pInfo->totalsize;
pInfo->offset = 0;
pInfo->video_info_nums = 0;
if(Video_Mem_Malloc( pInfo )==0)
__D(" MEM_INIT Success \n");
else
return -1;
MemMng_memcpy_open();
return 0;
MEM_INIT_FAIL:
__E(" MEM_INIT_FAIL \n");
return -1;
}
EDMA_Status EDMA_freeResource(int lch, int nParams)
{
EDMA_Status status = EDMA_OK;
struct EDMA_releaseDmaParams request;
int ioctl_status;
__D("freeResource: entered - lch=%d, nParams=%d\n", lch, nParams);
if (EDMA_dmaops_fd < 0) {
__D("freeResource: /dev/edma not opened\n");
return (EDMA_ENOINIT);
}
request.channel = lch;
request.nParam = nParams;
if ((ioctl_status = ioctl(EDMA_dmaops_fd,
EDMA_IOCRELEASEDMA | EDMA_IOCMAGIC,
(unsigned long)&request)) < 0) {
__E("EDMA_IOCRELEASEDMA error\n");
status = EDMA_EFAIL;
}
__D("freeResource: exiting, ioctl EDMA_IOCRELEASEDMA returned %d\n",
ioctl_status);
return (status);
}
EDMA_Status EDMA_registerResource(int lch)
{
EDMA_Status status = EDMA_OK;
int ioctl_status;
__D("registerResource: entered - lch=%d\n", lch);
if (EDMA_dmaops_fd < 0) {
__D("registerResource: /dev/edma not opened\n");
return (EDMA_ENOINIT);
}
if ((ioctl_status = ioctl(EDMA_dmaops_fd, EDMA_IOCREGUSER | EDMA_IOCMAGIC,
(unsigned long)&lch)) < 0) {
__E("EDMA_IOCREGUSER error\n");
status = EDMA_EFAIL;
}
__D("registerResource: exiting, ioctl EDMA_IOCREGUSER returned %d\n",
ioctl_status);
return (status);
}
int EDMA_getVersion(void)
{
unsigned int version;
int rv;
__D("getVersion: entered\n");
if (EDMA_dmaops_fd < 0) {
__D("getVersion: /dev/edma not opened\n");
return (EDMA_ENOINIT);
}
rv = ioctl(EDMA_dmaops_fd, EDMA_IOCGETVERSION | EDMA_IOCMAGIC, &version);
if (rv != 0) {
__E("getVersion: Failed to retrieve version from driver: %d.\n", rv);
return -1;
}
__D("getVersion: exiting, ioctl EDMA_IOCGETVERSION returned %#x\n",
version);
return version;
}
static int getBlock(int blockid, unsigned long *pphys_base, size_t *psize)
{
union CMEM_AllocUnion block;
int rv;
__D("getBlock: entered\n");
if (!validate_init()) {
return -1;
}
block.blockid = blockid;
rv = ioctl(cmem_fd, CMEM_IOCGETBLOCK | CMEM_IOCMAGIC, &block);
if (rv != 0) {
__E("getBlock: Failed to retrieve memory block bounds for block %d "
"from driver: %d.\n", blockid, rv);
return -1;
}
*pphys_base = block.get_block_outparams.physp;
*psize = block.get_block_outparams.size;
__D("getBlock: exiting, ioctl CMEM_IOCGETBLOCK succeeded, "
"returning *pphys_base=0x%lx, *psize=0x%x\n", *pphys_base, *psize);
return 0;
}
/**
* @brief Write cache
* @param "CACHE_DATA *pCache"
* @param "VIDEO_FRAME *pFrame"
* @param "VIDEO_BLK_INFO *pVidInfo"
* @return 0 ; CACHE_PARM_ERR
*/
int CacheMng_cache_write( CACHE_DATA *pCache, VIDEO_FRAME *pFrame, VIDEO_BLK_INFO *pVidInfo )
{
CACHE_BLK *pblk = NULL;
unsigned long Src_Addr = 0;
unsigned long Des_Addr = 0;
int size = 0;
int cnt = 0;
if( pCache==NULL || pFrame==NULL || pVidInfo==NULL )
{
__E("CacheMng_cache_write: invalidate parameter!! \n");
return CACHE_PARM_ERR;
}
pCache->fram_type = pFrame->fram_type;
pCache->serial = pFrame->serial;
pCache->realsize = pFrame->realsize;
pCache->flag = pFrame->flag;
pCache->timestamp = pFrame->timestamp;
pCache->temporalId = pFrame->temporalId;
for( cnt = 0; cnt < VIDOE_INFO_END; cnt++ )
{
pCache->ref_serial[cnt] = pFrame->ref_serial[cnt];
}
for( cnt = 0; cnt < pCache->blks ; cnt ++ )
{
pblk = &(pVidInfo->cachemng->blk[ pCache->blkindex + cnt ]);
CacheMng_blk_set( pblk, pCache->serial );
}
pblk = &(pVidInfo->cachemng->blk[ pCache->blkindex ]);
Des_Addr = pVidInfo->cachemng->start_addr + pblk->offset;
Src_Addr = pVidInfo->start + pVidInfo->blk_sz*pFrame->blkindex;
size = pCache->realsize;
if( CacheMng_MemCpy( (void *)Des_Addr, (void *)Src_Addr, size ) < 0 )
{
__E("CacheMng_cache_write: error memcpy \n");
return CACHE_PARM_ERR;
}
return 0;
}
static void *allocFromHeap(int blockid, size_t size, CMEM_AllocParams *params)
{
void *userp;
union CMEM_AllocUnion allocDesc;
unsigned long physp;
unsigned int cmd;
int rv;
cmd = CMEM_IOCALLOCHEAP | params->flags;
allocDesc.alloc_heap_inparams.size = size;
allocDesc.alloc_heap_inparams.align = params->alignment == 0 ?
1 : params->alignment;
allocDesc.alloc_heap_inparams.blockid = blockid;
rv = ioctl(cmem_fd, cmd | CMEM_IOCMAGIC, &allocDesc);
if (rv != 0) {
__E("allocHeap: ioctl %s failed: %d\n",
cmd == CMEM_IOCALLOCHEAP ?
"CMEM_IOCALLOCHEAP" : "CMEM_IOCALLOCHEAPCACHED",
rv);
return NULL;
}
physp = allocDesc.physp;
__D("allocHeap: allocated phys buffer %#lx\n", physp);
/* Map the physical address to user space */
userp = mmap(0, // Preferred start address
size, // Length to be mapped
PROT_WRITE | PROT_READ, // Read and write access
MAP_SHARED, // Shared memory
cmem_fd, // File descriptor
physp); // The byte offset from fd
if (userp == MAP_FAILED) {
__E("allocHeap: Failed to mmap buffer at physical address %#lx\n",
physp);
__E(" Freeing phys buffer %#lx\n", physp);
ioctl(cmem_fd, CMEM_IOCFREEHEAPPHYS | CMEM_IOCMAGIC, &physp);
return NULL;
}
__D("allocHeap: mmap succeeded, returning virt buffer %p\n", userp);
return userp;
}
/* RGB Buffer Allocation into frame buffer */
static int camif_pp_preview_msdma(camif_cfg_t *cfg)
{
int i;
u32 cbcr_size = 0; /* Cb+Cr size */
u32 val; //one_p_size, val;
u32 area = cfg->cis->source_x * cfg->cis->source_y;
__D("\n");
val = readl(S3C_VIDW01ADD0B0);
if(!((cfg->dst_fmt & CAMIF_RGB16) || (cfg->dst_fmt & CAMIF_RGB24)))
__E("Invalid Format\n");
for ( i = 0; i < 4 ; i++ ) {
base->CIPRYSA[i] = val;
}
if (cfg->src_fmt & CAMIF_YCBCR420) {
cbcr_size = area/4;
cfg->img_buf[0].virt_cb = cfg->pp_virt_buf + area;
cfg->img_buf[0].phys_cb = cfg->pp_phys_buf + area;
cfg->img_buf[0].virt_cr = cfg->pp_virt_buf + area + cbcr_size;
cfg->img_buf[0].phys_cr = cfg->pp_phys_buf + area + cbcr_size;
} else if(cfg->src_fmt & CAMIF_YCBCR422){
area = area * 2;
cfg->img_buf[0].virt_cb = 0;
cfg->img_buf[0].phys_cb = 0;
cfg->img_buf[0].virt_cr = 0;
cfg->img_buf[0].phys_cr = 0;
}
cfg->img_buf[0].virt_y = cfg->pp_virt_buf;
cfg->img_buf[0].phys_y = cfg->pp_phys_buf;
base->MSPRY0SA = cfg->img_buf[0].phys_y;
base->MSPRY0END = cfg->img_buf[0].phys_y+area;
base->MSPRCB0SA = cfg->img_buf[0].phys_cb;
base->MSPRCB0END = cfg->img_buf[0].phys_cb+cbcr_size;
base->MSPRCR0SA = cfg->img_buf[0].phys_cr;
base->MSPRCR0END = cfg->img_buf[0].phys_cr+cbcr_size;
#ifdef SW_IPC
base->MSCOWIDTH.AutoLoadEnable = 0; // AutoLoadDisable
#else
base->MSCOWIDTH.AutoLoadEnable = 1; // AutoLoadEnable
#endif
base->MSPRWIDTH.MSPRHEIGHT = cfg->cis->source_y;
base->MSPRWIDTH.MSPRHEIGHT = cfg->cis->source_x;
return 0;
}
/**
* @brief Destroy the semephore
* @param none
* @retval 0: success; -1: fail
*/
int Sem_kill()
{
if( pthread_mutex_destroy(&mutex)!= 0 )
{
__E("Sem_kill faill!!\n");
return -1;
}
return 0;
}
static void *allocFromPool(int blockid, int poolid, CMEM_AllocParams *params)
{
union CMEM_AllocUnion allocDesc;
unsigned long physp;
void *userp;
size_t size;
unsigned int cmd;
int rv;
allocDesc.alloc_pool_inparams.poolid = poolid;
allocDesc.alloc_pool_inparams.blockid = blockid;
cmd = CMEM_IOCALLOC | params->flags;
rv = ioctl(cmem_fd, cmd | CMEM_IOCMAGIC, &allocDesc);
if (rv != 0) {
__E("allocPool: ioctl %s failed from pool %d: %d\n",
cmd == CMEM_IOCALLOC ? "CMEM_IOCALLOC" : "CMEM_IOCALLOCCACHED",
poolid, rv);
return NULL;
}
physp = allocDesc.alloc_pool_outparams.physp;
size = allocDesc.alloc_pool_outparams.size;
__D("allocPool: allocated phys buffer %#lx, size %#x\n", physp, size);
/* Map the physical address to user space */
userp = mmap(0, // Preferred start address
size, // Length to be mapped
PROT_WRITE | PROT_READ, // Read and write access
MAP_SHARED, // Shared memory
cmem_fd, // File descriptor
physp); // The byte offset from fd
if (userp == MAP_FAILED) {
__E("allocPool: Failed to mmap buffer at physical address %#lx\n",
physp);
__E(" Freeing phys buffer %#lx\n", physp);
ioctl(cmem_fd, CMEM_IOCFREEPHYS | CMEM_IOCMAGIC , &physp);
return NULL;
}
__D("allocPool: mmap succeeded, returning virt buffer %p\n", userp);
return userp;
}
/**
* @brief Unset cache block
* @param "CACHE_BLK *pblk" : cache block
* @return none
*/
void CacheMng_blk_unset( CACHE_BLK *pblk)
{
if( pblk )
{
pblk->IsFree = 1;
pblk->serial = -1;
} else {
__E("CacheMng_blk_unset : NULL \n");
}
}
/**
* @brief read dm355 gio infomation
*
*@param gio_id GIO ID
* @return GIO status
*@retval -1 error
*/
int dm355_gio_read( int gio_id )
{
int fd_gio = 0;
char data[5];
int result = 0;
char dev_name[25];
if( gio_id < 0 || gio_id > GIO_MAX_ID )
{
__E("gio id = %d over range!!\n", gio_id);
return -1;
}
if( dm355_gio_getname(dev_name,gio_id) < 0 )
{
__E("gio get name error!!\n");
return -1;
}
fd_gio = open(dev_name, O_RDWR);
if( !fd_gio )
{
__E("open device error !! gio = %d\n", gio_id);
return -1;
}
result = read(fd_gio, data, 1);
if( result <= 0 )
{
__E("read device error !! gio = %d\n", gio_id);
close(fd_gio);
return -1;
}
close(fd_gio);
if( data[0] == '1')
{
return 1;
}else{
return 0;
}
return -1;
}
/*
* Codec Input YCBCR422 will be Fixed
* cfg->flip removed because cfg->flip will be set in camif_change_flip func.
*/
static int camif_target_fmt(camif_cfg_t *cfg)
{
//u32 cmd = 0;
__D("\n");
if (cfg->dma_type & CAMIF_CODEC) {
base->CICOTRGFMT.TargetHsize_Co = cfg->target_x;
base->CICOTRGFMT.TargetVsize_Co = cfg->target_y;
/* YCBCR setting */
if ( cfg->dst_fmt & CAMIF_YCBCR420 ) {
base->CICOTRGFMT.OutFormat_Co = 0; //Interleadve Off
} else if(cfg->dst_fmt & CAMIF_YCBCR422) {
if(cfg->interlace_capture)
base->CICOTRGFMT.OutFormat_Co = 2;
else
base->CICOTRGFMT.OutFormat_Co = 1;
} else if((cfg->dst_fmt & CAMIF_RGB24) ||(cfg->dst_fmt & CAMIF_RGB16)) {
base->CICOTRGFMT.OutFormat_Co = 3;
} else {
__E("camif_target_fmt() - Invalid Format\n");
}
} else if (cfg->dma_type & CAMIF_PREVIEW) {
base->CIPRTRGFMT.TargetHsize_Pr = cfg->target_x;
base->CIPRTRGFMT.TargetVsize_Pr = cfg->target_y;
/* YCBCR setting */
if ( cfg->dst_fmt & CAMIF_YCBCR420 ) {
base->CIPRTRGFMT.OutFormat_Pr = 0;
} else if(cfg->dst_fmt & CAMIF_YCBCR422) {
base->CIPRTRGFMT.OutFormat_Pr = 1;
} else if((cfg->dst_fmt & CAMIF_RGB24) ||(cfg->dst_fmt & CAMIF_RGB16)) {
base->CIPRTRGFMT.OutFormat_Pr = 3;
} else {
__E("Invalid Format\n");
}
} else {
__E("Failed! %d\n", cfg->dma_type);
}
return 0;
}
/**
* @brief Set cache block
* @param "CACHE_BLK *pblk" : cache block
* @param "int serial" : serial number
* @return none
*/
void CacheMng_blk_set( CACHE_BLK *pblk, int serial)
{
if( pblk )
{
pblk->IsFree = 0;
pblk->serial = serial;
} else {
__E("CacheMng_blk_set : NULL \n");
}
}
/**
* @brief Initialize the mutex which protects the global data
* @param none
* @retval 0: success; -1: fail
*/
int Sem_Creat()
{
/* Initialize the mutex which protects the global data */
if( pthread_mutex_init(&mutex, NULL) != 0 )
{
__E("Sem_Creat init faill!!\n");
return -1;
}
return 0;
}
/**
* @brief Create a semaphore
* @param "int index" : index
* @return index : success ; -1 : fail
*/
int Sem_Creat( int index )
{
if( index < 0 || index >= STREAM_SEM_NUM)
{
__E("Sem_Creat index faill!!\n");
return -1;
}
/* Initialize the mutex which protects the global data */
if( pthread_mutex_init(&stream_mutex[index], NULL) != 0 )
{
__E("Sem_Creat init faill!!\n");
return -1;
}else{
return index;
}
}
/**
* @brief Destroy a semaphore
* @param "int index" : index
* @return 0 : success ; -1 : fail
*/
int Sem_kill( int index )
{
if( index < 0 || index >= STREAM_SEM_NUM)
{
__E("Sem_kill index faill!!\n");
return -1;
}
if( pthread_mutex_destroy(&stream_mutex[index])!= 0 )
{
__E("Sem_kill faill!!\n");
return -1;
}
return 0;
}
/**
* @brief Lock a semaphore
* @param "int index" : index
* @return 0 : success ; -1 : fail
*/
int Sem_lock( int index )
{
if( index < 0 || index >= STREAM_SEM_NUM)
{
__E("Sem_lock faill!!!!!!!!!!!!!!!!!!!!!!!!!!!\n");
return -1;
}
pthread_mutex_lock(&stream_mutex[index]);
return 0;
}
/**
* @brief Reset cache block
* @param "CACHE_BLK *pblk" : cache block
* @param "int offset" : offset
* @return none
*/
void CacheMng_blk_reset( CACHE_BLK *pblk, int offset)
{
if( pblk )
{
pblk->IsFree = 1;
pblk->offset = offset;
pblk->serial = -1;
} else {
__E("CacheMng_blk_reset : NULL \n");
}
}
void *CMEM_registerAlloc(unsigned long physp)
{
union CMEM_AllocUnion allocDesc;
void *userp;
size_t size;
int rv;
allocDesc.physp = physp;
rv = ioctl(cmem_fd, CMEM_IOCREGUSER | CMEM_IOCMAGIC, &allocDesc);
if (rv != 0) {
__E("registerAlloc: ioctl CMEM_IOCREGUSER failed for phys addr %#lx: %d\n",
physp, rv);
return NULL;
}
size = allocDesc.size;
__D("registerAlloc: registered use of phys buffer %#lx, size %#x\n",
physp, size);
/* Map the physical address to user space */
userp = mmap(0, // Preferred start address
size, // Length to be mapped
PROT_WRITE | PROT_READ, // Read and write access
MAP_SHARED, // Shared memory
cmem_fd, // File descriptor
physp); // The byte offset from fd
if (userp == MAP_FAILED) {
__E("registerAlloc: Failed to mmap buffer at physical address %#lx\n",
physp);
__E(" Unregistering use of phys buffer %#lx\n", physp);
ioctl(cmem_fd, CMEM_IOCFREEPHYS | CMEM_IOCMAGIC, &physp);
return NULL;
}
__D("registerAlloc: mmap succeeded, returning virt buffer %p\n", userp);
return userp;
}
